Back to EveryPatent.com
| United States Patent |
5,613,133
|
|
Bell
, et al.
|
March 18, 1997
|
Microcode loading with continued program execution
Abstract
Microcode is loaded into, for example, a processor or I/O module within a
computer system without manually halting and restarting the computer
system. In other words, microcode can be loaded into the computer system
dynamically while data processing continues from the processor or I/O
module states just prior to the microcode load with no major interruption
to the user. A microcode image is loaded into a processor which is already
executing one or more tasks. A request to load microcode into the
processor is received. The processor is signalled to suspend task
execution. After the microcode image is transferred into the processor,
the processor is signalled to resume task execution.
| Inventors:
|
Bell; Michael (Glen Mills, PA);
Burroughs; William (Exton, PA);
Gilliam; Susanne (Radnor, PA);
Holman; William (Coatesville, PA)
|
| Assignee:
|
Unisys Corporation (Blue Bell, PA)
|
| Appl. No.:
|
303493 |
| Filed:
|
September 9, 1994 |
| Current U.S. Class: |
717/162 |
| Intern'l Class: |
G06F 009/26; G06F 009/18 |
| Field of Search: |
395/775,375,700
|
References Cited
U.S. Patent Documents
| 4204252 | May., 1980 | Hitz et al. | 395/775.
|
| 4422144 | Dec., 1983 | Johnson et al. | 395/375.
|
| 5278973 | Jan., 1994 | O'Brien et al. | 395/500.
|
| 5511195 | Apr., 1996 | Kennedy, Jr. et al. | 395/650.
|
Primary Examiner: Harvey; Jack B.
Assistant Examiner: Seto; Jeffrey K.
Attorney, Agent or Firm: Sowell, Att.; John B., Starr, Att.; Mark T., O'Rourke, Att.; John F.
Claims
What is claimed:
1. A method of loading a microcode image into a processor in a computer
system, wherein said processor is executing one or more tasks, said method
comprising the steps of:
receiving a request to load microcode into said processor,
signalling said processor to suspend execution of said one or more tasks;
suspending execution of said one or more tasks at respective states of said
one or more tasks;
transferring said microcode image into said processor;
signalling said processor to resume execution of said one or more tasks;
and
resuming execution of said one or more tasks at said respective states.
2. A method of loading a microcode image into a processor in a computer
system in accordance with claim 1, wherein said computer system includes a
coprocessor for sending messages to said processor, and said step of
signalling said processor to suspend execution of said one or more tasks
includes the steps of:
signalling to said coprocessor to suspend execution of said one or more
tasks; and
signalling from said coprocessor to said processor to suspend execution of
said one or more tasks.
3. A method of loading a microcode image into a processor in a computer
system in accordance with claim 1, wherein said computer system includes
an operating system for receiving said request to load microcode into said
processor and wherein said operating system transmits a signal for said
processor to suspend execution of said one or more tasks.
4. A method of loading a microcode image into a processor in a computer
system in accordance with claim 2, wherein said coprocessor is a console,
said microcode image is stored in said console and said microcode image is
transferred from said console to said processor after said processor
suspends execution of said one or more tasks.
5. A method of loading a microcode image into a processor in a computer
system in accordance with claim 4, wherein said computer system includes a
memory and said processor includes a cache memory associated with and
corresponding to address space in said memory, and wherein said
coprocessor transfers data from said cache memory to said memory prior to
transferring said microcode image from said console to said processor.
6. A method of loading a microcode image into a plurality of processors in
a computer system, wherein each of said processors is executing one or
more tasks, comprising the steps of:
receiving a request to load said microcode image into said plurality of
processors;
signalling a first one of said plurality of processors to suspend operation
of said one or more tasks;
suspending execution of said one or more tasks executed by said first one
of said plurality of processors at a first plurality of respective states;
transferring said microcode image into said first one of said plurality of
processors;
signalling said first one of said plurality of processors to resume
operation of said one or more tasks at said first plurality of respective
states;
signalling a second one of said plurality of processors to suspend
operation of said one or more tasks;
suspending execution of said one or more tasks executed by said second one
of said plurality of processors at a second plurality of respective
states;
transferring said microcode image into said second one of said plurality of
processors; and
signalling said second one of said plurality of processors to resume
operation of said one or more tasks at said second plurality of respective
states.
7. A method of loading a microcode image into a plurality of processors in
a computer system according to claim 6, wherein said computer system
includes an operating system for receiving said request to load microcode
into said plurality of processors and wherein said operating transmits at
least one signal to said plurality of processors to suspend execution of
said one or more tasks.
8. A method of loading a microcode image into a plurality of processors in
a computer system according to claim 6, wherein said microcode image is
stored in a coprocessor which is coupled to said computer system and said
microcode image is transferred from said coprocessor to each of said
plurality of processors after each of said plurality of processors
suspends execution of said one or more tasks.
9. A method of loading a microcode image into a plurality of processors in
a computer system according to claim 8, wherein said coprocessor is a
console, said computer system includes a memory and each of said
processors includes a cache memory associated with and corresponding to
address space in said memory, and wherein one of said plurality of
processors transfers data from said cache memory of another one of said
processors to said memory prior to said console transferring said
microcode image to said another one of said processors.
10. A method of loading a microcode image into a plurality of processors in
a computer system according to claim 6, wherein two of said plurality of
processors are input/output (I/O) processors for coordinating I/O
operations and wherein one of said two I/O processors is selected to
handle message exchange between said plurality of processors while another
of said two I/O processors is receiving said microcode image.
11. Apparatus for loading a microcode image into a processor in a computer
system wherein said processor executes a plurality of tasks, comprising
the steps of:
suspension means for suspending execution of said plurality of tasks by
said processor at a respective plurality of states;
means for transferring said microcode image into said processor, and
means for resuming execution of said plurality of tasks by said processor
at said respective plurality of states.
12. Apparatus for loading a microcode image into a processor in a computer
system according to claim 11, wherein said suspension means comprises a
coprocessor for receiving a request to suspend execution of said plurality
of tasks and for transmitting a signal for said processor to suspend
execution of said plurality of tasks.
13. Apparatus for loading a microcode image into a processor in a computer
system according to claim 11, wherein said computer system includes an
operating system for receiving a request to load microcode into said
processor and for transmitting a signal to said processor to suspend
execution of said one or more tasks.
14. Apparatus for loading a microcode image into a processor in a computer
system according to claim 12, wherein said microcode image is stored in
said coprocessor, said coprocessor further including means for
transferring said microcode image from said coprocessor to said processor
after said processor suspends execution of said one or more tasks.
15. Apparatus for loading a microcode image into a processor in a computer
system according to claim 14, wherein said computer system includes a
memory and said processor includes a cache memory associated with and
corresponding to address space in said memory, and wherein said
coprocessor includes means for transferring data from said cache memory to
said memory prior to transferring said microcode image from said
coprocessor to said processor.
16. Apparatus for loading a microcode image into a plurality of processors
in a computer system, wherein said plurality of processors executes a
plurality of tasks, comprising:
means for suspending execution of said plurality of tasks by said first one
of said plurality of processors at a respective plurality of states;
means for transferring said microcode image into said first one of said
plurality of processors;
means for resuming execution of said plurality of tasks by said first
processor at said respective plurality of states;
means for suspending execution of said plurality of tasks by said second
one of said plurality of processors at a further respective plurality of
states;
means for transferring said microcode image into said second one of said
plurality of processors, and
means for resuming execution of said plurality of tasks by said second
processor at said further respective plurality of states.
17. Apparatus for loading a microcode image into a plurality of processors
in a computer system according to claim 16, wherein said computer system
includes an operating system for receiving said request to load microcode
into said plurality of processors and for transmitting at least one signal
to said plurality of processors to suspend execution of said plurality of
tasks.
18. Apparatus for loading a microcode image into a plurality of processors
in a computer system according to claim 16, further comprising coprocessor
means in which said microcode image is stored, said coprocessor including
means for transferring said microcode image from said coprocessor to each
of said plurality of processors after each of said plurality of processors
suspends execution of said plurality of tasks.
19. Apparatus for loading a microcode image into a plurality of processors
in a computer system according to claim 18, wherein said computer system
includes a memory and each of said processors includes a cache memory
associated with and corresponding to address space in said memory, one of
said plurality of processors comprising means for transferring data from
said cache memory of another one of said processors to said memory prior
to said console transferring said microcode image to said another one of
said processors.
20. Apparatus for loading a microcode image into a plurality of processors
in a computer system according to claim 16, wherein two of said plurality
of processors includes means for coordinating I/O operations, said
apparatus further comprising means for selecting one of said two I/O
processors to handle message exchange between said plurality of processors
while another of said two I/O processors is receiving said microcode
image.
Description
FIELD OF THE INVENTION
This invention is in the field of computer systems. In particular, a
computer system and method are disclosed in which microcode may be loaded
into a processor or I/O module without halting or restarting the computer
system and with continued program execution.
BACKGROUND OF THE INVENTION
Modern computer systems are comprised of a plurality of processors, each
performing dedicated functions. By using multiple processors, improved
throughput is obtained.
A block diagram which illustrates the modularity of a modern computer
system is set forth in FIG. 1. Computer system 100 illustrates a computer
system architecture which may apply, for example, to an A16 mainframe
(manufactured by Unisys Corporation, Blue Bell, Pa.). As illustrated by
FIG. 1, the plurality of processors may be segregated into two separate
partitions, with first domain 120 occupying one partition and second
domain 130 occupying another partition. In this way, each partition is
able to independently execute isolated tasks.
In some computer systems, multiple segregated processors (i.e. multiple
domains) may be included in each partition for higher levels of
independent but concurrent processing. Alternatively, if required, the two
partitions can be combined to intercommunicate for processor intensive
task execution. As a further alternative, first domain 120 may exist with
second domain 130 deleted.
For simplicity, the components within computer system 100 will be described
with regard to first domain 120. However, it is understood that many of
the components found in first domain 120 are also found in second domain
130 (if second domain 130 is included).
A central processing module (CPM) 122 is responsible for many types of code
execution. As one example, CPM 122 executes the operating system--referred
to as the Master Control Program (MCP). Each program executed by CPM 122
performs separate procedures, referred to as "tasks".
Terminal 160 receives user instructions (for example, through a keyboard)
and transfers the user instructions to the MCP being executed by CPM 122.
Results of various tasks being executed by CPM 122 are communicated to the
user by terminal 160.
Input/output module (IOM) 124 coordinates input/output (I/O) operations.
IOM 124 is comprised of a plurality of units which coordinate I/O
operations. One type of unit included in IOM 124 is input/output unit
(IOU) 141. IOU 141 performs high level I/O functions such as the
scheduling of I/O jobs, the selection of data paths over which I/O jobs
are performed, the gathering of job statics and the management of I/O
devices. Another type of unit included in IOM 124 is task control unit
(TCU) 142. TCU 142 provides allocating and de-allocating of events,
maintaining the status of tasks running on the system, performing of task
priority computations and scheduling the execution of tasks.
For simplicity, CPM 122 and IOM 124 (and any other central processing
modules and I/O modules in computer system 100) will each be referred to
as requestors.
Memory storage module (MSM) 128 includes various memory components where
program code and data may be stored. CPM 122 is able to communicate with
MSM 128. Thus, for example, CPM 122 executes program code (e.g. the code
for the MCP) stored in MSM 128. In addition, IOM 124 is able to
communicate with MSM 128. Each requestor includes a memory cache to
facilitate data storage and retrieval operations with MSM 128.
State access module (SAM) 126 provides host maintenance logic. SAM 126 is
capable of viewing the state of CPM 122, IOM 124, and MSM 128.
Console (or coprocessor) 150 is coupled to each module (CPM 122, IOM 124,
SAM 126 and MSM 128). Console 150 displays the state of each module and
the state of MSM 128. Console 150 also invokes software
routines--maintenance access commands (MACs)--which are executed by SAM
126 for providing data transfer functions to or between console 150 and
requestors.
In accordance with the prior art, CPM 122 and IOM 124 include modularized
hardware architectures which are capable of performing data processing.
However, as is well known in the art, such hardware architectures perform
processing responsive to microcode loaded therein. The loaded microcode
directs the hardware to perform the transfer of data between various
internal components (e.g. processors, requestors, memory, registers, etc.)
according to predetermined timing sequences.
The ability to alter microcode within CPM 122 or IOM 124 facilitates
modification of the operation of CPM 122 and IOM 124. Put another way,
should a modification in the operation of CPM 122 and IOM 124 be desired,
expensive hardware modifications are typically not necessary. All that is
required is to load different microcode into these devices.
In accordance with the prior art, it is common for computer systems to stop
processing and come to a complete halt in order to load new microcode.
After restarting the system, tasks that were interrupted at the time of
system halt typically cannot simply "resume" execution at the point of
interruption. Instead, tasks may be started from their respective
beginnings with their previous results (or intermediate results) lost.
Thus, downtime of the computer system is required with a significant
impact on system productivity. Furthermore, interrupted tasks may require
complete re-execution.
For example, many computer systems may have hundreds of tasks currently in
various stages of execution. The complete stoppage of such a computer
system is a significant inconvenience and major expense to the users of
such systems. Furthermore, after the new microcode has been loaded, either
a system re-boot or special types of re-configuration action are required.
This may be significantly time consuming and require the use of expensive
engineering resources.
Various system reconfigurations may be attempted to load new microcode
without incurring the aforementioned difficulties. Such reconfigurations
are tedious to implement and often not successful.
SUMMARY OF THE INVENTION
A microcode image is loaded into a processor in a computer system which is
already executing one or more tasks. A request to load microcode into the
processor is received. The processor is signalled to suspend task
execution. After the microcode image is transferred to the processor, the
processor is signalled to resume task execution. Thus, a microcode image
is loaded into the processor dynamically while data processing continues
with no major interruption to the user. Furthermore, following the loading
of the microcode, task execution may continue from the point of execution
prior to the microcode load.
BRIEF DESCRIPTION OF THE FIGURES
FIG. 1 is a block diagram of a computer system in accordance with the prior
art.
FIG. 2 is flow chart diagram which is useful for providing a generalized
explanation of the operation of a first exemplary embodiment of the
present invention.
FIG. 3 is flow chart diagram which is useful for providing a generalized
explanation of the operation of a second exemplary embodiment of the
present invention.
FIG. 4a is a block diagram which illustrates the transfer of data and
signals between various hardware and software components in accordance
with the first exemplary embodiment of the present invention.
FIG. 4b is a block diagram which illustrates the transfer of data and
signals between various hardware and software components in accordance
with the second exemplary embodiment of the present invention.
FIG. 5 is a flow chart diagram which is useful for explaining the operation
of both the first and the second exemplary embodiments of the present
invention.
DETAILED DESCRIPTION OF THE INVENTION
The present invention provides a reliable process for loading microcode
into, for example, a processor or I/O module in a computer system without
manually halting the computer system and without reinitiating executing
tasks which were interrupted by the microcode load. In other words,
microcode can be loaded into the computer system dynamically while
processing continues with no major interruption to the user. This process
of dynamically loading microcode is referred to as live domain microcode
loading.
The operation of a first exemplary embodiment of the present invention is
generally illustrated by FIG. 2. The first exemplary embodiment of the
present invention is intended for live domain microcode loading of a
single requestor in a computer system. This embodiment is applicable when
there is only one requestor (i.e. physically on the system or in use) that
is to receive the microcode load.
As shown in FIG. 2, step 210, a user initiates the process of live domain
microcode loading through the use of an operator command. This typically
occurs by the user typing the appropriate request into terminal 160. In
response to the operator command, at step 220, the operating system
transmits appropriate signals so that console 150 is advised of the user's
live domain microcode Loading request. At step 230, the console transmits
appropriate signals to all of the requestors in computer system 100 to
suspend task execution. At step 240, console 150 loads the microcode into
the appropriate requestor. Finally, at step 250, console 150 signals all
of the requestors in computer system 100 to resume task processing.
A second exemplary embodiment of the present invention is generally
illustrated by the flow chart diagram of FIG. 3. The second exemplary
embodiment of the present invention is intended for live domain microcode
loading of multiple requestors in a computer system.
As shown in FIG. 3, step 310, the user initiates the process of live domain
microcode loading with an operator command. This typically occurs by the
user typing the appropriate request into terminal 160.
Depending on the requestor that is to receive the microcode load, the
operating system idles the requestor and transmits an appropriate signal
to console 150 indicating that a microcode load is requested. At step 330,
the microcode is transferred from the console to the specified requestor.
At step 340, it is determined if further requestors require live domain
microcode loading. If an additional requestor requires live domain
microcode loading, then execution is transferred again to step 320. If
there are no further requestors that require live domain microcode
loading, then the loading sequence is terminated.
Both exemplary embodiments may include the step of advising the user of the
completion of the requested live domain microcode loading.
Appropriate hardware and software structures which implement exemplary
embodiments of the present invention are logically shown in FIG. 4a and
FIG. 4b. FIG. 4a and FIG. 4b each include components included in FIG. 1.
These components are rearranged and shown with additional components for
explanatory purposes. FIG. 4a is intended to illustrate the operation of
the flow chart diagram which is included in FIG. 2. FIG. 4b is intended to
illustrate the operation of the flow chart diagram which is included in
FIG. 3.
As shown in FIG. 4a, terminal 160 is capable of receiving appropriate
commands from the user. In accordance with the present invention, the user
indicates that live domain microcode loading is desired.
Thus, the user may enter a load microcode command. The command includes the
type of requestor (i.e. CPM or IOM) to load and the version of microcode
to load. Terminal 160 transmits the user's request to load microcode to
the master control program 420 (i.e. the operating system being executed
from MSM 128 by CPM 122). Upon receipt of the user's load microcode
request from terminal 160, MCP 420 communicates with the requestor to
ensure that the requestor is in a suitable state for halting. For example,
in the case of IOM 124, MCP 420 communicates with IOM 124 to ensure that
IOM 124 is not in actively in the middle of an I/O operation. Upon MCP 420
ensuring that the requestor is in a suitable state for halting, MCP 420
sends a message to TCU 142 requesting that TCU 142 set an internal flag.
Console 150 routinely polls the flag register within TCU 142. Upon
determining that the flag within TCU 142 is set, console 150 begins to
process the user's live domain microcode loading request as more clearly
set forth below.
Console 150 desirably first invokes appropriate MACs to turn off all system
clocks within computer system 100.
Console 150 then performs Memory Updating. Memory Updating is performed as
follows.
To maintain data integrity, it is desirable to ensure that the memory space
in MSM 128 includes all of the contents of the memory cache of requestor
450 prior to microcode load. Thus, console 150 transfers the contents of
the cache of requestor 450 into the corresponding memory space in MSM 128.
Next, console 150 makes several determinations including a) whether the
flag within TCU 142 was set responsive to user's live domain microcode
loading request (the flag may have other functions), b) whether the user's
request is valid, c) whether the microcode which the user wishes to load
is stored in console 150 (where microcode for live domain microcode
loading requests is desirably stored), d) whether the microcode which the
user wanted loaded into requestor 450 is compatible with microcode which
has been running on computer system 100, and e) whether the microcode
which the user wishes to load has already been loaded into requestor 450.
If the flag within TCU 142 was not set as a result of a live domain
microcode loading request, other action as appropriate is taken. If there
is a problem with request validity, microcode availability, microcode
compatibility, or if the microcode is already in the requestor, an
appropriate message (e.g. an error message) is created, the console
signals the idled requestors in computer system 100 to resume processing,
and MCP 420 provides the user with a message identifying the condition.
If the appropriate conditions outlined above are met, console 150 invokes
and SAM 126 executes appropriate MACs to transfer the appropriate
microcode from console 150 to SAM 126. As the microcode is transferred to
SAM 126, the MACs executed by SAM 126 transfer and load the microcode into
requestor 450.
After completing the loading of the live domain microcode into requestor
450, the MACs executed by SAM 126 transmit a message to console 150
indicating the completion (and the success or failure) of the microcode
load. Console 150 then invokes appropriate MACs which are executed by SAM
126 to signal CPM 122 and IOM 124 to resume task execution. With CPM 122
again enabled, MCP 420 is again enabled. Thus MCP can again assume its
supervisory role. MCP 420 informs the user via terminal 160 that
processing is complete.
The block diagram of FIG. 4b illustrates an alternative manner of loading
live domain microcode into a requestor. However, the embodiment shown in
FIG. 4b is intended for the loading of microcode into multiple requestors.
In accordance with the present invention, the user indicates that live
domain microcode loading is desired. Thus, the user may enter a load
microcode command which includes the type of requestor to receive the
microcode load and the version of microcode to be loaded. Terminal 160
transmits the user's request to load microcode to the master control
program 420 (i.e. the operating system being executed from MSM 128 by CPM
122). Upon receipt of the user's load microcode request from terminal 160,
MCP 420 performs several operations. One operation performed by MCP 420 in
this embodiment is, based on the type of requestor specified by the user,
to evaluate a list of requestors to determine the specific requestor which
is to be loaded with the microcode. Another operation performed by MCP 420
is to idle the specific requestor for which the loading of live domain
microcode is being attempted. With regard to FIG. 4b, the loading of live
domain microcode load is being attempted for requestor 450 (i.e. CPM 122,
CPM 132, IOM 124, IOM 134). The idling of a requestor is explained below.
If CPM 132 is the requestor that is being idled (i.e. requestor 450), MCP
420 signals TCU 124 that CPM 132 is being idled. TCU 124 then signals CPM
132 to stop processing (i.e. in a stack machine, for CPM 132 to stop
processing the stack currently being processed by CPM 132). CPM 132 is
then instructed to go into an "idle" mode (i.e. to not execute further
code) until further instructions are received. TCU 124 then signals CPM
122 that CPM 132 has been idled. In response, CPM 122 removes CPM 132 from
a list of available requestors. In this way, no further tasks will be
assigned by computer system 100 to CPM 132 until the loading of microcode
into CPM 132 has been completed.
MCP 420 next directs CPM 122 (the non idle CPM) to perform Memory Updating.
Memory Updating is performed in the manner described with reference to
FIG. 4a.
MCP 420 then sends a message to the console 150 requesting live domain
microcode loading. If the conditions generally described above with
reference to FIG. 4a are not met (e.g. request validity, microcode
availability, microcode compatibility, microcode already in the
requestor), then the microcode load attempt is terminated with an
appropriate message (e.g. an error message) from console 150 to MCP 420
and a subsequent message from MCP 420 to the user. Otherwise, the
microcode is transferred to SAM 126, and the MACs executed by SAM 126
transfer and load the code image into requestor 450.
After completing the loading of the live domain microcode into requestor
450, the MACs executed by SAM 126 transmit a message to console 150
indicating the completion (and the success or failure) of the microcode
load. Console 150 then passes this information on to MCP 420 (via an
appropriate message) and MCP 420 passes this information on to the user
(by a further appropriate message). Next, MCP 420 signals TCU 142 that
requestor 450 is ready to accept tasks. TCU 142 begins assigning tasks to
requestor 450, enables operation of requestor 450 and signals MCP 420 that
requestor 450 may be assigned tasks. The entire process can then be
repeated for another requestor. MCP 420 informs the user via terminal 410
when processing is complete.
Although the explanation provided above relates to the loading of microcode
into any type of requestor, there are somewhat different procedures for
loading microcode depending upon whether the requestor is a CPM (e.g. CPM
122) or an IOM (IOM 124).
The most significant difference between the loading of microcode in CPM 122
or IOM 124 occurs at the step of idling the requestor prior to the
microcode load and readying the request after the microcode load. For
purposes of this explanation, an IOM is considered to be either
distinguished or undistinguished. This designation is used because, when
there is more than one IOM in computer system 100 (i.e. when there are two
IOMs in computer system 100), there is a TCU and IOU in each IOM. One
TCU/IOU set is used to pass messages back and forth to the remaining
processors in computer system 100. The remaining processors in computer
system 100 need to known which TCU/IOU set is actually passing the
messages. Accordingly, the IOU and TCU which are passing messages between
the remaining processors are referred to as the distinguished IOU and the
distinguished TCU, respectively. Each processor is advised as to which TCU
is the distinguished TCU and which IOU is the distinguished IOU. Upon
being appropriately advised, the remaining processors in computer system
100 use the distinguished TCU and the distinguished IOU for interprocessor
message transmission.
When microcode is being loaded into the two IOMs in computer system 100,
the non-distinguished IOM (i.e. the IOM that does not include the
distinguished TCU and the distinguished IOU) is loaded first. After the
non-distinguished IOM has been loaded, the console transfers the data held
in the distinguished TCU and the distinguished IOU to the
non-distinguished IOM. The non-distinguished IOM is then made into the
distinguished IOM. Similarly, the distinguished IOM is then made the
nondistinguished IOM. By proceeding according to the method explained
above, the data stored in the originally distinguished IOM is not lost.
After the data from the originally distinguished IOM is transferred to the
new distinguished IOM, the microcode in the originally distinguished IOM
can be updated. Thus, while initializing each IOM during the loading of
the live domain microcode, data is not lost.
An alternative manner of explaining the operation of the present invention
is provided by the exemplary embodiment of the present invention which is
shown in FIG. 5.
Execution of the exemplary embodiment of the present invention is initiated
either by steps 502 and 506 or by steps 504 and 508. Execution is
initiated at steps 502 and 506 when console 150 detects a Communicate
message. Communicate messages are used when there is live domain microcode
loading of a single requestor in computer system 100. Execution is
initiated at steps 504 and 508 when console 150 receives an @Domain
message. @Domain messages are used when there is live domain microcode
loading of multiple requestors in computer system 100.
Thus, at step 502, the console 150 detects that a flag within TCU 124 has
been set by MCP 420 and, at step 506, turns off the clocks of each
requestor. If the flag in TCU 124 does not indicate a request for a live
domain microcode load, then alternative processing as appropriate is
performed (step 510). Otherwise, processing proceeds to step 512.
Alternatively, at step 504, MCP 420 transmits a request directly to console
150 (in the form of an I/O request) indicating that live domain microcode
loading is desired. At step 508, console 150 acknowledges the request.
Processing again proceeds to step 512.
At step 512, the request for live domain microcode loading is evaluated to
determine whether the request is valid and to determine if the requested
microcode currently exists within console 150.
At step 514, a determination is made as to whether the live domain
microcode which is desired to be loaded has already been loaded. If the
live domain microcode has already been loaded, then execution is
transferred to step 530 after which MCP 420 is appropriately notified. If
the microcode has not already been loaded, then, at step 516, a
compatibility check is made. This involves determining whether the
microcode to be loaded is compatible with the type of microcode presently
running on that type of requestor within the system. In an exemplary
embodiment of the present invention, compatibility may be determined by
evaluating the version numbers (or other appropriate identification
numbers) of the presently running microcode. If the microcodes are not
compatible, then execution transfers to step 528 (to indicate the problem
to MCP 420).
Execution of the present algorithm then varies depending on whether the
microcode is to be loaded into CPM 122 or IOM 124. If CPM 122 is to be
loaded with microcode then, at step 522, the appropriate MACs are called
to load the microcode. If IOM 124 is to be loaded, then, at step 524,
various states in the IOM are saved, hardware fail reports are collected,
the microcode is loaded and the IOM is appropriately initialized. If there
is more than one IOM, then the undistinguished and distinguished IOMs are
loaded with microcode in the manner previously described. At step 526, the
clocks are started and the halt switches are reset. The maintenance bus
which was used to load the microcode into requestor 450 is disabled.
It is then determined whether the microcode load was successful. If the
microcode load was successful, execution transfers to step 530 (to
indicate the good result to the MCP). Conversely, if the microcode load
was not successful, then execution transfers to step 528 (to indicate the
problem to MCP 420). Finally, at steps 532 and 534, the user is advised of
the failure and success of the microcode load, respectively.
While the invention has been described in terms of exemplary embodiments,
it is contemplated that it may be practiced as outlined above with
modifications within the spirit and scope of the appended claims.
Top